Ball game racquet, especially tennis racquet

ABSTRACT

The ball sport or ball game racquet, in particular tennis racquet, having a racquet frame for holding stringing and a racquet shaft extending from the racquet frame and having one racquet grip, wherein the racquet frame and the racquet shaft both are formed from a hollow frame profile with a plurality of walls. In at least one of the walls of the racquet frame and/or of the racquet shaft, at least one spacing layer is provided at least in some sections for increasing the stability of the ball sport racquet.

BACKGROUND OF THE INVENTION

The invention relates to a ball sport or ball game racquet, in particular a tennis racquet, with a racquet frame for holding the stringing and with a shaft extending from the racquet frame and with a racquet grip. The racquet frame and the racquet shaft both feature a hollow frame profile made up of a plurality of walls or wall sections. The invention also relates to a method for manufacturing a hollow frame profile for such a ball sport racquet.

Modern ball sport or ball game racquets, in particular tennis racquets, consist among other things of a racquet frame and a racquet shaft extending from and connected with this racquet frame. The racquet frame and the racquet shaft are manufactured from an outwardly closed hollow frame profile, which normally is made from a plurality of prepreg layers that are pressed together to form closed hollow frame profile.

Prepreg layers are layers of synthetic or plastic material reinforced by fibers, such as carbon fibers, glass fibers and also other fibers, which are pre-impregnated with resin. Prepreg layers can be designed as woven prepreg layers, which are pre-impregnated in form of unidirectional and multi-axial layers. Depending on the requirements for the component to be manufactured, various resins are used, especially epoxide or epoxy resins and phenolic resins, both of which hardly flow at room temperature. In order to manufacture a hollow frame profile from such prepreg layers, the prepreg layers are placed in cold condition in a pre-defined mold and hardened under pressure and application of heat. Especially the application of heat causes the resin to liquefy temporarily so that it impregnates the fibers before it begins to harden.

Various methods, in particular the blow molding methods, are known for manufacturing a racquet frame and racquet shaft featuring a hollow frame profile with a pre-defined wall thickness and fiber orientation and a defined outer contour and surface. In the blow molding method, a plurality of prepreg layers or prepreg layer windings are placed carefully and load-oriented on or around a core, which for example is covered with a tube, and pressed under high pressure into a female mold and hardened to achieve a defined surface and outer contour. In heavily stressed zones, it is possible to include additional prepreg layers at particular locations, in order to achieve different wall thicknesses while maintaining the same outer diameter, if required.

Furthermore, the wall thicknesses and the outer diameters of the hollow frame profile have a significant influence on the playability of a tennis racquet, so that especially tennis racquets for amateur and hobby use have a very high and wide hollow frame profile with a wall thickness of less than 1 mm in order to achieve a very high degree of stiffness in combination with low weight (less than 200 g). The hollow frame profile of the racquet frame and of the racquet shaft comprises for example four opposing walls in pairs, which can have one left and right opposing wall, each with a height of up to 30 mm or more and one upper and lower opposing wall, each with a width of up to 15 mm or more, to form a honeycomb cross section.

Individually, neither the upper and lower walls nor the left and right walls of the hollow frame profile are stiff; rather, they receive the necessary stiffness by suitably connecting the corresponding walls.

It is an object of the present invention is to provide for a ball sport racquet of the type mentioned at the outset featuring a sufficiently high degree of stiffness despite a high and wide hollow frame profile.

SUMMARY OF THE INVENTION

This object is achieved by a ball sport or ball game racquet, in particular tennis racquet, with a racquet frame for holding the stringing and with a shaft extending from the racquet frame and with a racquet grip, wherein the racquet frame and the racquet shaft both feature a hollow frame profile made up of a plurality of walls or wall sections, and wherein at least one of the walls of the racquet frame and/or of the racquet shaft features at least in some sections at least one spacing layer for increasing the stability of the ball sport racquet.

The increase of stability is not or only to a small extend obtained by the stability or strength of the material of the spacing layer itself, but mainly by the fact that prepreg layers or the windings of the wall or wall section are spaced from another by the spacing layer and that by that the moment of inertia of the wall and the stiffness the wall are increased without substantially increasing the weight of the ball sport racquet.

The use of a spacing layer in at least one of the walls of the hollow frame profile of a ball sport racquet according to the invention, on at least one or more wall sections, significantly increases the stiffness of the overall racquet frame. Preferably the spacing layer is provided in-between the wall layers forming the wall or wall section, that means in-between two windings in the shaft area and in the upper and lower wall sections of the hollow frame profile, if the hollow frame profile is made by winding the prepreg material around a core.

The spacing layer is manufactured from a porous or honeycomb material, which is for example known from airplane construction. Alternatively, various foam materials can be used for manufacturing the spacing layer, due to their low volume weight. The density of the material used should be considerably below the density of the prepreg layers, which have a density of approx. 1.9 g/cm³. The materials used preferably have a density of less than 1.0 g/cm³ while also featuring a high degree of compressive strength. This is of particular importance, since when applying the blow molding method for manufacturing the hollow frame profile of the tennis racquet, pressures of more than 8 bar can occur, so that the material used as the spacing layer must be able to withstand such high pressures during the production process.

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the invention are described below with reference to the drawings, in which:

FIG. 1 shows a simplified representation in top view of a ball sport racquet in the form of a tennis racquet;

FIG. 2 shows a simplified representation in cross section corresponding to the line 1-1 of FIG. 1;

FIG. 3 shows a simplified representation in cross section corresponding to the line 11-11 of FIG. 1;

FIG. 4 shows a simplified representation of shaft area of the ball sport racquet in the form of a tennis racquet; and

FIG. 5 shows a simplified representation of single selected production steps for a hollow frame profile manufactured according to the blow molding process.

DETAILED DESCRIPTION OF THE INVENTION

The tennis racquet depicted in the drawings and generally designated 1 consists essentially of a racquet frame 2 forming the racquet head, of the stringing 3 located there, which comprises a plurality of crisscrossing string lengths 4′, 4″ or strings 4, and of a racquet shaft 6 connecting to the racquet frame 2 by means of a throat or heart 5 and on which (shaft) a racquet grip 7 is provided. The throat 5 is connected with the racquet frame 2 in the connecting areas 5′, 5″.

The racquet frame 2 features an outwardly closed hollow frame profile 8, which is manufactured for example from a plurality of prepreg layers according to the blow molding process.

To exemplify the structure of the hollow frame profile 8 of the racquet frame 2 and of the racquet shaft 6, FIG. 2 shows a cross section corresponding to the line 1-1 of FIG. 1. The hollow frame profile 8 features by way of example an oval cross section flattened on two opposing sides each being at a distance form the stinging and parallel or nearly parallel with the stringing. The hollow frame profile 8 features a hollow space 9, which is surrounded by the walls of a plurality of prepreg layers or windings 10.

The hollow frame profile 8 in the depicted embodiment consists of one upper and lower, opposing flat or nearly flat wall sections 8.1, 8.2 and one left and right, likewise opposing wall sections 8.3, 8.4. In alternative embodiments, additional walls or wall sections can be provided for forming the hollow frame profile 8. The walls 8.1 and 8.2 are located on different sides of the strings 3 or stringing 4, each with the greater distance from these strings. The hollow frame profile 8 has for example a wall thickness W of approximately 1.0 mm. The upper and lower wall sections 8.1, 8.2 are parallel to each other in the depicted embodiment and are separated from each other by the hollow space 9. The left and right wall sections 8.3, 8.4 extend in the shape of a circular arc in order to form the honeycomb cross section, wherein the inner circular arc sections of the left and right wall sections 8.3, 8.4 face the hollow space 9. The wall sections 8.1-8.4 merge with each other.

FIG. 3 shows a cross section corresponding to the line 11-11 of FIG. 1 through one of the two hollow frame profiles 8 of the throat 5. The upper and lower wall sections 8.1, 8.2 of the hollow frame profile 8 feature an upper and lower spacing layer 11, 12, which are embedded between one upper and lower prepreg winding layer 10.1, 10.2 in the upper and lower wall sections 8.1 and 8.2.

The spacing layer 11, 12 is manufactured from a honeycomb material 11.1, 12.1, which is for example known from airplane construction. Alternatively, a foam material with a low volume weight can be used. In a preferred embodiment, the density of the material 11.1, 12.1 is less than 1.0 g/cm³ and therefore considerably less than the density of the prepreg layers 10 (approx. 1.9 g/cm³). In addition, the material 11.1, 12.1 of the spacing layers 11, 12 has a compressive strength greater than 8.0×10⁵ N/m² in order to be able to withstand the pressures of more than 8 bar occurring during the production process when the blow molding process is used to manufacture the hollow frame profile 8.

FIG. 4 shows the shaft area of the tennis racquet 1, in particular the throat 5 with one first and second hollow frame profile 8 a, 8 b, both of which are connected via the racquet shaft 6. In addition to the second hollow frame profile 8 b, the figure depicts a spacing layer 11 extending over the depicted hollow frame profile 8 a, 8 b and possessing the same curvature and which is inserted during the manufacturing process for the tennis racquet 1 for example into the upper wall section 8.1 of the second hollow frame profile 8 b to increase the stiffness of the tennis racquet 1, particularly in the shaft area. The insertion point of the spacing layer 11 in the throat 5 of the shaft area of the tennis racquet 1 is indicated by two arrows, which point to the upper wall section 8.1 of the second hollow frame profile 8 b.

The racquet shaft 6 also features a hollow frame profile 13, which consists of upper and lower walls or wall sections 13.1, 13.2 and left and right walls or wall sections 13.3, 13.4. Furthermore, the hollow frame profile 13 of the racquet shaft 6 also features one first and second connecting section 14, 15, by means of which the first and second hollow frame profile 8 a, 8 b of the throat 5 are connected with the racquet shaft 6. The first and second connection sections 14, 15 are provided on the end of the racquet shaft 6 facing the racquet head and are connected with each other by means of a preferably semi-circular connecting element 16, which closes the hollow space 17 of the hollow frame profile 13 of the racquet shaft 6 toward the outside.

In a preferred embodiment, the spacing layer 11 is inserted into the upper wall section 6.1 of the hollow frame profile 8 a of the throat 5 so that it projects at least partially over the second connecting section 15 into the racquet shaft 6 and therefore is integrated into the upper wall section 13.1 of the hollow frame profile 13 of the racquet shaft 6. Similar to FIG. 3, a plurality of first and second spacing layers 11, 12 can be provide both in the upper and in the lower wall sections 6.1, 6.2 of the hollow frame profile 8 a, 8 b or 13.1, 13.2, said spacing layers being brought together or located parallel to each other in the shaft area and in particular below the connecting element 16.

In alternative embodiments, the spacing layers 11, 12 can also be provided in different sections of the hollow frame profile 8 of the racquet frame 6; in particular, the spacing layers 11, 12 can extend either individually or in pairs over the connecting areas 5′-5″ between the throat 5 and the racquet frame 2. Also, the alternating integration of the spacing layers 11, 12 in sections of the upper and/or lower wall sections 8.1, 8.2 or 13.1, 13.2 of the tennis racquet 1 is possible.

FIG. 5 shows by way of example a simplified depiction of the hollow frame profile 8 in various stages of production during the manufacture of the hollow frame profile 8 according to the blow molding process. In a first production step (a) the prepreg layers 10 are oriented carefully according to the load and then placed by winding on a core (not depicted in FIG. 5) covered with a hose. This forms at least one first prepreg layer 10.1 for achieving the upper and lower as well as left and right wall sections 8.1 through 8.4.

In a second production step (b), one first and second spacing layer 11, 12 made of the material 11.1, 12.1 described above are placed on the at least first prepreg layer 10.1 in the upper and lower wall area and surrounded with at least one second prepreg winding or layer 10.2. The spacing layers 11, 12 of the hollow frame profile 8 that are already surrounded by a plurality of further prepreg layers 10 are shown in a further production step (c) in FIG. 5.

Afterwards, the prepreg layers 10 including the spacing layers 11, 12 are pressed to the hollow frame profile 8 according to FIG. 3 under application of heat. The application of heat causes the resin provided in the prepreg layers 10 to liquefy, bonding the synthetic layers and the spacing layers 11, 12 embedded therein, which then are compressed to a stiff hollow frame profile 8, 8 a, 8 b in the pressing process. The hollow frame profile 8, 8 a, 8 b created by the heating and pressing process is shown in FIG. 5 in a fourth production step (d).

The invention was described above based on exemplary embodiments. It goes without saying that numerous modifications and alterations are possible without abandoning the underlying inventive idea upon which the invention is based.

REFERENCE NUMBERS

-   1 tennis racquet -   2 tension frame -   3 stringing -   4 strings -   4′ string length -   5 throat -   5′, 5″ connecting area -   6 shaft -   7 grip -   8 hollow frame profile -   8.1 upper wall or wall section -   8.2 lower wall or wall section -   8.3 left wall or wall section -   8.4 right wall or wall section -   9 hollow space of hollow frame profile -   10 prepreg layers -   10.1 first prepreg layers or windings -   10.2 second prepreg layers or windings -   11 first spacing layer -   11.1 material of first spacing layer -   12 second spacing layer -   12.1 material of second spacing layer -   13 hollow frame profile of shaft -   13.1 upper wall or wall section -   13.2 lower wall or wall section -   13.3 left wall or wall section -   13.4 right wall or wall section -   14 first connecting section -   15 second connecting section -   16 connecting piece -   17 hollow space -   W wall thickness -   L length of hollow frame profile of the throat 

1. A ball sport or ball game racquet, comprising a racquet frame for holding the stringing and with a shaft extending from the racquet frame and a racquet grip, wherein the racquet frame and the racquet shaft both feature a hollow frame profile consisting of a plurality of walls or wall sections, and wherein at least one of the walls or wall sections of the racquet frame and/or of the racquet shaft features at least in some sections at least one spacing layer for increasing the stability of the ball sport racquet.
 2. The racquet according to claim 1, wherein the hollow frame profile of the racquet frame, the racquet shaft, or both the racquet frame and the racquet shaft, feature one upper and lower wall or wall sections and that at least one spacing layer is provided in the upper and/or lower wall or wall section.
 3. The racquet according to claim 1, wherein the hollow frame profile of the racquet frame, the racquet shaft, or both the racquet frame and the racquet shaft, feature one upper and lower wall or wall sections and that at least one spacing layer is only provided in the upper and/or lower wall or wall section.
 4. The racquet according to claim 1, wherein the walls of the racquet frame, the racquet shaft, or both the racquet frame and the racquet shaft, comprise prepreg layers or windings of prepreg material.
 5. The racquet according to claim 4, wherein the spacing layer is provided between at least two prepreg layers of the walls or wall sections.
 6. The racquet according to claim 4, wherein the spacing layer is provided between windings of prepreg material of the walls or wall sections.
 7. The racquet according to claim 1, wherein the walls or wall sections located away from a level of the stringing or being distanced from the stringing comprise the spacing layer.
 8. The racquet according to claim 1, wherein the spacing layer extends over at least two connecting sections between the racquet frame and the racquet shaft.
 9. The racquet according to claim 1, wherein the at least one spacing layer is provided at least in some sections in the hollow frame profile of a throat of the ball sport racquet.
 10. The racquet according to claim 1, wherein the spacing layer is made of a material with a honeycomb structure.
 11. The racquet according to claim 1, wherein the spacing layer is made of a foam material.
 12. The racquet according to claim 1, wherein the spacing layer is made of a material with a density of less than 1.9 g/cm³ or with a compressive strength greater than 8.0×10⁵ N/m².
 13. The racquet according to claim 1, wherein the spacing layer is made of a material with a low volume weight.
 14. The racquet according to claim 7, wherein the walls or wall sections located away from the level of the stringing or being distanced from the stringing are fattened.
 15. The racquet according to claim 1, wherein the first and second prepreg layers are each formed by at least one winding of the prepreg material.
 16. A blow molding method for manufacturing a hollow frame profile for a ball sport or ball game racquet, comprising the following steps: covering a production tube with at least one first prepreg layer; application of at least one spacing layer on at least one upper and/or lower section of the first prepreg layer; covering the at least first prepreg layer and the at least one spacing layer with at least one second prepreg layer; pressing the at least first and second prepreg layer together with the integrated at least one spacing layer under application of heat to manufacture a hollow frame profile consisting of the at least one upper and lower wall or wall section.
 17. The method according to claim 16, wherein the at least one spacing layer is applied to at least one first prepreg layer forming one upper and/or lower wall.
 18. The method according to claim 16, wherein the at least one first spacing layer is applied to at least one first prepreg layer at a position forming an upper wall or wall section of the hollow frame profile and at least one second spacing layer is applied to said at least one first prepreg layer at a position forming an lower wall or wall section of the hollow frame profile, said at least one first and second spacing layers being distanced from another such that the hollow frame profile comprises inner and outer walls or wall sections without a spacing layer in between the upper and lower walls or wall sections.
 19. The method according to claim 16, wherein the first and second prepreg layers are each formed by at least one winding of the prepreg material.
 20. The method according to claim 16, wherein the at least one spacing layer is applied in the area of a throat of the ball sport racquet. 